Femoral and tibial base components

ABSTRACT

Various embodiments are directed to base components that are usable with implantable mechanical energy absorbing systems. According to one embodiment, the base component includes a low-profile body having a elongate, straight portion at a first end and a curved body portion at a second end. The second end is elevated as compared to the first end. An inner surface of the low-profile body has a raised portion extending along the elongate, straight portion of the low-profile body. The base component also includes a plurality of openings positioned along the low-profile body for alignment and purposes of affixation to body anatomy.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a continuation-in-part of U.S. application Ser. No.11/743,097, filed May 1, 2007, a continuation-in-part of U.S.application Ser. No. 11/743,605, filed May 2, 2007, acontinuation-in-part of U.S. application Ser. No. 11/775,139, filed Jul.9, 2007, now U.S. Pat. No. 7,611,540, a continuation-in-part of U.S.application Ser. No. 11/775,149, filed Jul. 9, 2007, now U.S. Pat. No.7,655,041, and a continuation-in-part of U.S. application Ser. No.11/775,145, filed Jul. 9, 2007, now U.S. Pat. No. 7,678,147, the entiredisclosures of which are expressly incorporated herein by reference.

FIELD OF EMBODIMENTS

Various embodiments disclosed herein are directed to structure forattachment to body anatomy, and more particularly, towards approachesfor providing mounting members for extra-articular implantablemechanical energy absorbing systems.

BACKGROUND

Joint replacement is one of the most common and successful operations inmodern orthopaedic surgery. It consists of replacing painful, arthritic,worn or diseased parts of a joint with artificial surfaces shaped insuch a way as to allow joint movement. Osteoarthritis is a commondiagnosis leading to joint replacement. Such procedures are a lastresort treatment as they are highly invasive and require substantialperiods of recovery. Total joint replacement, also known as total jointarthroplasty, is a procedure in which all articular surfaces at a jointare replaced. This contrasts with hemiarthroplasty (half arthroplasty)in which only one bone's articular surface at a joint is replaced andunincompartmental arthroplasty in which the articular surfaces of onlyone of multiple compartments at a joint (such as the surfaces of thethigh and shin bones on just the inner side or just the outer side atthe knee) are replaced. Arthroplasty as a general term, is anorthopaedic procedure which surgically alters the natural joint in someway. This includes procedures in which the arthritic or dysfunctionaljoint surface is replaced with something else, procedures which areundertaken to reshape or realigning the joint by osteotomy or some otherprocedure. As with joint replacement, these other arthroplastyprocedures are also characterized by relatively long recovery times andtheir highly invasive procedures. A previously popular form ofarthroplasty was interpositional arthroplasty in which the joint wassurgically altered by insertion of some other tissue like skin, muscleor tendon within the articular space to keep inflammatory surfacesapart. Another previously done arthroplasty was excisional arthroplastyin which articular surfaces were removed leaving scar tissue to fill inthe gap. Among other types of arthroplasty are resection(al)arthroplasty, resurfacing arthroplasty, mold arthroplasty, cuparthroplasty, silicone replacement arthroplasty, and osteotomy to affectjoint alignment or restore or modify joint congruity. When it issuccessful, arthroplasty results in new joint surfaces which serve thesame function in the joint as did the surfaces that were removed. Anychodrocytes (cells that control the creation and maintenance ofarticular joint surfaces), however, are either removed as part of thearthroplasty, or left to contend with the resulting joint anatomy.Because of this, none of these currently available therapies arechondro-protective.

A widely-applied type of osteotomy is one in which bones are surgicallycut to improve alignment. A misalignment due to injury or disease in ajoint relative to the direction of load can result in an imbalance offorces and pain in the affected joint. The goal of osteotomy is tosurgically re-align the bones at a joint and thereby relieve pain byequalizing forces across the joint. This can also increase the lifespanof the joint. When addressing osteoarthritis in the knee joint, thisprocedure involves surgical re-alignment of the joint by cutting andreattaching part of one of the bones at the knee to change the jointalignment, and this procedure is often used in younger, more active orheavier patients. Most often, high tibial osteotomy (HTO) (the surgicalre-alignment of the upper end of the shin bone (tibia) to address kneemalalignment) is the osteotomy procedure done to address osteoarthritisand it often results in a decrease in pain and improved function.However, HTO does not address ligamentous instability—only mechanicalalignment. HTO is associated with good early results, but resultsdeteriorate over time.

Other approaches to treating osteoarthritis involve an analysis of loadswhich exist at a joint. Both cartilage and bone are living tissues thatrespond and adapt to the loads they experience. Within a nominal rangeof loading, bone and cartilage remain healthy and viable. If the loadfalls below the nominal range for extended periods of time, bone andcartilage can become softer and weaker (atrophy). If the load risesabove the nominal level for extended periods of time, bone can becomestiffer and stronger (hypertrophy). Finally, if the load rises too high,then abrupt failure of bone, cartilage and other tissues can result.Accordingly, it has been concluded that the treatment of osteoarthritisand other bone and cartilage conditions is severely hampered when asurgeon is not able to precisely control and prescribe the levels ofjoint load. Furthermore, bone healing research has shown that somemechanical stimulation can enhance the healing response and it is likelythat the optimum regime for a cartilage/bone graft or construct willinvolve different levels of load over time, e.g. during a particulartreatment schedule. Thus, there is a need for devices which facilitatethe control of load on a joint undergoing treatment or therapy, tothereby enable use of the joint within a healthy loading zone.

Certain other approaches to treating osteoarthritis contemplate externaldevices such as braces or fixators which attempt to control the motionof the bones at a joint or apply cross-loads at a joint to shift loadfrom one side of the joint to the other. A number of these approacheshave had some success in alleviating pain but have ultimately beenunsuccessful due to lack of patient compliance or the inability of thedevices to facilitate and support the natural motion and function of thediseased joint. The loads acting at any given joint and the motions ofthe bones at that joint are unique to the body that the joint is a partof. For this reason, any proposed treatment based on those loads andmotions must account for this variability to be universally successful.The mechanical approaches to treating osteoarthritis have not taken thisinto account and have consequently had limited success.

Prior approaches to treating osteoarthritis have also failed to accountfor all of the basic functions of the various structures of a joint incombination with its unique movement. In addition to addressing theloads and motions at a joint, an ultimately successful approach mustalso acknowledge the dampening and energy absorption functions of theanatomy, and be implantable via a minimally invasive technique. Priordevices designed to reduce the load transferred by the natural jointtypically incorporate relatively rigid constructs that areincompressible. Mechanical energy (E) is the action of a force (F)through a distance (s) (i.e., E=F^(x)s). Device constructs which arerelatively rigid do not allow substantial energy storage as the forcesacting on them do not produce substantial deformations—do not actthrough substantial distances—within them. For these relatively rigidconstructs, energy is transferred rather than stored or absorbedrelative to a joint. By contrast, the natural joint is a constructcomprised of elements of different compliance characteristics such asbone, cartilage, synovial fluid, muscles, tendons, ligaments, etc. asdescribed above. These dynamic elements include relatively compliantones (ligaments, tendons, fluid, cartilage) which allow for substantialenergy absorption and storage, and relatively stiffer ones (bone) thatallow for efficient energy transfer. The cartilage in a joint compressesunder applied force and the resultant force displacement productrepresents the energy absorbed by cartilage. The fluid content ofcartilage also acts to stiffen its response to load applied quickly anddampen its response to loads applied slowly. In this way, cartilage actsto absorb and store, as well as to dissipate energy.

With the foregoing applications in mind, it has been found to benecessary to develop effective structure for mounting to body anatomy.Such structure should conform to body anatomy and cooperate with bodyanatomy to achieve desired load reduction, energy absorption, energystorage, and energy transfer. The structure should also provide a basefor attachment of complementary structure across articulating joints.

For these implant structures to function optimally, they must not causea disturbance to apposing tissue in the body, nor should their functionbe affected by anatomical tissue and structures impinging on them.Moreover, there is a need to reliably and durably transfer loads acrossmembers defining a joint. Such transfer can only be accomplished wherethe base structure is securely affixed to anatomy. Therefore, what isneeded is an approach which addresses both joint movement and varyingloads as well as complements underlying anatomy and provides aneffective base for connecting an implantable extra-articular assembly.

SUMMARY

Briefly, and in general terms, the disclosure is directed to basecomponents that are mountable to a bone and may be used for cooperationwith an implantable extra-articular system. In one approach, the basecomponents facilitate mounting an extra-articular implantable link ormechanical energy absorbing system.

According to one embodiment, the base components of the link or energyabsorbing system are contoured to the bone surfaces of the femur andtibia and are secured with bone screws on the medial cortices of thefemur and the tibia. The bases can also be attached to lateral sides ofthe bones of a knee joint or on either side of members defining otherjoints. The base components are also designed to preserve thearticulating joint and capsular structures of the knee. Accordingly,various knee procedures, including uni-compartmental and total jointreplacement, may be subsequently performed without requiring removal ofthe base components.

In one specific embodiment, the base component includes a body having aninner surface that is contoured to mate with a bone surface. The innersurface contacts the bone surface and may be porous, roughened or etchedto promote osteointegration. The inner surface can be coated with anosteointegration composition. Optionally, or additionally, the basecomponent is secured to a bone surface with a plurality of fasteningmembers. The base component is also shaped to avoid and preservestructures of the knee. Moreover, the base component is configured tolocate a mounting member on the bone in order to position a kinematicload absorber for optimal reduction of forces on a joint. The basecomponent is a rigid structure that may be made from titanium, cobaltchrome, or polyetheretherketones (PEEK). In an alternate approach, thebase can be formed at least partially from flexible material.

It is contemplated that the base component includes a low-profile bodyhaving an elongate, straight portion at a first end portion and a curvedbody portion at a second end portion. The second end portion is elevatedas compared to the first end portion and occupies a plane displaced fromthe first end. An inner surface of the low-profile body has a raisedportion extending along the elongate, straight portion of the body. Thebase component also includes a plurality of openings positioned alongthe elongate portion of the body. Additionally, the body can include twoopenings positioned side-by-side on the curved portion thereof.

According to another embodiment, the base component is a generallycurved body having a first end, a second end, an outer surface, and aninner surface. The curved body is non-planar such that the second end ofthe body is elevated as compared to the first end of the body. In anapplication relating to treating a knee joint, the inner surface of thebody includes a raised portion that is contoured to the medial surfaceof the femur above the medial epicondyle. The body also includes aplurality of openings, wherein two openings are positioned side-by-sidenear the second end. Additionally, the openings provide differingtrajectories for receiving fastening members.

In one particular approach, the disclosed base has an osteointegrationsurface area greater than 39 mm². More specifically, a femoral basecomponent can embody a surface area of 971 mm² and a tibial componentcan have a surface area of approximately 886 mm². The bases can furtherbe coated with a titanium plasma spray having a thickness of 0.033inches plus or minus 0.005 inches. Alternatively, an hydroxyapatiteplasma spray resulting in a 35 μm plus or minus 10 μm thickness iscontemplated.

Moreover, it is contemplated that various sized bases be made available.In that regard, due to expected variability in anatomy, up to five ormore femoral base sizes and two or more tibial base sizes can beavailable to a physician.

The bases can be configured so that relative motion between a basecomponent and a mating bone is less than 150 microns. For certainapplications, the durability of the base to bone connection as well asmaterial should be such that the structure can withstand five millioncycles of functional loading.

Other features and advantages will become apparent from the followingdetailed description, taken in conjunction with the accompanyingdrawings, which illustrate by way of example, the features of thevarious embodiments.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1A is a perspective view of one embodiment of a base component.

FIG. 1B is a perspective view of the base component of FIG. 1A mountedto a bone.

FIG. 1C is a perspective view of another embodiment of a base component.

FIG. 1D is a side view depicting the base component of FIG. 1C mountedto a bone.

FIG. 2 is side view of a femur and indicates a preferred location of apivot point for an extra-articular mechanical energy absorbing system.

FIG. 3 is a side view of another embodiment of a base component formounting to a bone.

FIG. 4 is view of an inner surface of the base component shown in FIG.3.

FIG. 5 is a side view of the base component shown in FIG. 3 mounted on abone.

FIG. 6 is a side view of an alternate embodiment of a base component formounting to a bone.

FIG. 7 is a side view of an inner surface of the base component shown inFIG. 6.

FIG. 8 is a perspective view of the inner surface of the base componentshown in FIG. 6.

FIG. 9A is a cross-section view of the end of the base component thatreceives a mounting member.

FIG. 9B is a cross-sectional view of the end of the base component shownin FIG. 3.

FIG. 9C is a perspective view of the sleeve shown in FIG. 9B.

FIG. 10A is a side view of another embodiment of an inner surface of thebase component for mounting to a bone.

FIG. 10B is a perspective view of yet another embodiment of innersurface of the base component.

FIG. 11 is a side view of one embodiment of a base component fixed to afemur.

FIG. 12 is a front view of one embodiment of a base component fixed tothe medial surface of a femur.

FIG. 13 is a perspective view of another embodiment of a base componentfor mounting to a bone.

FIG. 14 is a perspective view of an inner surface of the base componentshown in FIG. 13.

FIG. 15A is a cross-section view of one embodiment of the base componentshown in FIG. 14.

FIG. 15B is a cross-section view of one embodiment of a portion of thebase component shown in FIG. 14.

FIG. 16 is a front view of the base component of FIG. 13 mounted to themedial surface of a tibia.

FIG. 17 is a side view of the base component of FIG. 13 mounted to themedial surface of the tibia.

FIG. 18 is a side view of a juxtapositional relationship of the basecomponents to one embodiment of an extra-articular implantablemechanical energy absorbing system.

FIG. 19 is a front view of the embodiment shown in FIG. 18.

FIGS. 20A-B are side views of base components having flexible regions.

FIGS. 21A-B are perspective views of an adjustable base assembly.

FIG. 22 is a perspective view of another embodiment of a base.

FIG. 23 is a perspective view of a first approach to a base assemblywith mounting structure extending laterally on a bone.

FIG. 24 is a perspective view of a second approach to a base assemblywith mounting structure extending laterally.

FIG. 25 is a perspective view of a third approach to a base assemblywith mounting structure extending laterally.

FIG. 26 is a perspective view illustrating a base component withstructure supported by anatomy.

FIG. 27 is a perspective view depicting a base including multiplecomponents.

FIG. 28 is a perspective view depicting yet another approach to asupported base assembly.

FIG. 29 is a perspective view of a base including tissue in-growthpromoting substructure.

FIG. 30 is a perspective view of another base including in-growthpromoting substructure.

FIG. 31 is a perspective view of yet another approach to a basecomponent.

FIG. 32 is a perspective view of yet a further approach to a basecomponent.

FIG. 33 is a perspective view of a base component including a slottedportion.

FIG. 34 is a perspective view depicting a base component with codedholes.

DETAILED DESCRIPTION

Various embodiments are disclosed which are directed to base componentsfor attachment to body anatomy. In a preferred approach, femoral andtibial base components are provided for attachment to extra-articularimplantable link or mechanical energy absorbing systems.

In a specific embodiment, the femoral and tibial base components arecontoured to the medial surfaces of the femur and tibia, respectively.The base components have a low-profile design and contoured surfacesthereby minimizing the profile of the base components when mounted tothe bone surface and enabling atraumatic soft tissue motions over thebone components. The base component is secured to a bone surface withone or more fastening members. Optionally, or additionally, the innersurface of the base components may be modified to promoteosteointegration of the base component into bone. Osteointegration is aprocess of bone growth onto and about an implanted device that resultsin integrating the implant to the bone, thereby facilitating thetransfer of load and stress from the implant directly to the bone. Afterosteointegration, fasteners used to initially attach the base componentto bone no longer are needed to carry the load and stress from theimplant.

The base component can be configured to be an anchor for theextra-articular implantable link or mechanical energy absorbing systemused to reduce forces on the knee or other joints (e.g., finger, toe,elbow). The base component can be also designed to distribute loads ontothe bone from an extra-articular implantable link or mechanical energyabsorbing system while avoiding articulating joint and capsularstructures.

Various shapes of bases are contemplated and described. Moreover, it iscontemplated that various sized and similar shaped bases be madeavailable to a physician so that a proper fit to variably sized andshaped bones can be accomplished. In that regard, it is contemplatedthat up to five or more different femoral bases and two or moredifferent tibial bases can be available to a physician.

The base components disclosed herein are structures that are differentand distinct from bone plates. As defined by the American Academy ofOrthopedic Surgeons, bone plates are internal splints that holdfractured ends of bone together. In contrast, the base componentsdisclosed herein are designed to couple to and transfer loads from alink of an implanted extra-articular system to the bones of the joint.Furthermore, the loading conditions of a bone plate system are directlyproportional to the physiological loads of the bone it is attached to,by contrast the loading conditions of a base is not directlyproportional to the physiological loading conditions of the bone but isdirectly proportional to the loading conditions of the link to which itis coupled. In various embodiments, the base component is configured totransfer the load through a combination of the fastening members used tosecure the base component to the bone and/or one or moreosteointegration areas on the base component.

Further, previous approaches and studies on osteointegration surfaceshave not considered cyclic loading. Thus, the approaches to the basesdisclosed herein address needs in this area and in particular, providesan approach which achieves extra-cortical boney in-growth under cyclicloading. In certain disclosed applications, a shear strength of about 3MPa or more can be expected.

Referring now to the drawings, wherein like reference numerals denotelike or corresponding parts throughout the drawings and, moreparticularly to FIGS. 1-20B, there are shown various embodiments of abase component that may be fixed to a bone. In one specific application,the base components are configured to be affixed to members defining ajoint. Moreover, in one particularly specific approach, the base can beconfigured to include a surface contacting periosteum.

Turning now to FIGS. 1A-1B, a base component 1 fixable to the medialsurface of a femur is illustrated. It is to be recognized, however, thatthe base component 1 can be configured to be fixed to a lateral side ofthe femur, on the tibia, or other anatomy of the body. The basecomponent 1 includes an outer surface 3 and an inner surface 5. Theouter surface 3 of the base component has a low-profile and is curved toeliminate any edges or surfaces that may damage surrounding tissue whenthe base component is affixed to bone. The base component 1 includes alocking hole 2 that locates a coupling structure 15 adjacent point 17(FIG. 2). The femoral base component 1 is intended to be positionedabout the center 19 of knee rotation in FIG. 2. According to oneembodiment, the base component 1 is mounted to the femur so that thecoupling structure 15 is located approximately 6 mm anterior andapproximately 1 mm superior to the center 19 of rotation of the knee onthe medial epicondyle. Such spacing is relevant to each of the disclosedembodiments. Mounting the energy absorbing components at this locationallows the extra-articular mechanical energy absorbing system to reduceforces during the heal strike to toe-off phase of a person's gait.Alternatively, the base component may be mounted at different positionson the femur to reduce forces during different phases of a person'sgait.

FIGS. 1C-D illustrate another embodiment of a base component 1 mountableon the medial surface of the femur. Again, it is noted that thisembodiment of the base component 1 can be positioned laterally as wellas on other anatomy. The base component 1 includes a raised surface 9 tosuspend the taper locking opening 2 higher off the bone surface to avoidthe knee capsule and associated structures of the knee joint. It iscontemplated that the taper locking opening 2 be offset approximately 10mm or less from the surface of the joint capsule. In one specificembodiment, the taper locking opening 2 is offset approximately 3 mmfrom the capsular structure. In another approach, the taper lockingopening 2 is offset approximately 6 mm from the capsular structure.Accordingly, the base component 1 allows for positioning of anextra-articular device on the knee joint while preserving the knee forprocedures such as ACL or PCL repair or replacement, Pes replacement, ortotal knee replacement.

It is contemplated that the inner surface of the base component 1 becontoured to directly contact the bone surface. The inner surface may becurved in an anterior to posterior direction as well as superior toinferior directions. According to one embodiment, the inner surfaceincludes one or more compositions that induce osteointegration to thecortex of long bones in the body. The inner surface represents the basecomponent 1 to bone surface area required to support expected shearforces resulting from 40 lbs. of load carrying. Alternatively, the innersurface 5 is roughened or etched to improve osteointegration.

The surface area of the osteointegration area is proportional to theforces being carried at a joint by the extra-articular mechanical energyabsorbing system. For example, the surface area of the inner surface isat least 39 mm² for a secure fixation to the femur and in order to carry40 pounds in 4 mm of compression of a kinematic load absorber. A safetyfactor may be built into base component as larger surfaces may be usedin other embodiments. For example, a femoral base component can includean osteointegration surface area of approximately 971 mm².Alternatively, a tibial base component includes an osteointegrationsurface area of approximately 886 mm².

In certain embodiments, the load transferred from the absorber to thebase component can change over time. For example, when the basecomponent is initially fixed to the bone, the fastening members carryall the load. Over time, as the base component osteointegrates with theunderlying bone, both the fastening members and the osteointegratedsurface carry the load from the implanted system. Once the basecomponent is completely osteointegrated with the underlying bone, theosteointegration area carries most (if not all) the load. Due to thesame, the energy absorbing system may be configured in an inactivestate, only later activating the device once sufficient osteointegrationhas occurred.

Alternatively, the implant may be intended for temporary use and soremovability of the components is important. In these instances boneyin-growth is not desirable. To prevent boney in-growth no porous coatingis applied and alternative surface geometry and/or material may be usedthat does not encourage bone growth, additionally the fasteners aredesigned to carry 100% of link loads for duration of implantation.

The base component also includes a plurality of openings 7 that aresized to receive fastening members used to permanently secure the basecomponent to the bone. The openings 7 define through-holes that mayreceive fastening members such as compression screws and/or lockingscrews. As shown in FIGS. 1A-D, the openings 7 are spaced about theouter surface 3 of the base component 1. In one embodiment, the openingscan be positioned on the outer surface 3 such that they are located asclose as possible to the taper locking opening 2. The openings 7 mayalso have divergent bore trajectories to further maximize the pullforces required to remove the base component from the bone. The numberand trajectories of the openings may be varied in alternate embodiments.

FIGS. 3-4 illustrate another embodiment of a base component 10. The basecomponent includes a body that is configured to position a mountingmember (not shown) at a point 17 superior and anterior to the center 19of knee rotation on the medial epicondyle as shown in FIG. 2. The basecomponent 10 also includes osteointegration rods 25 that extend alongthe surface of the bone. It is contemplated that the osteointegrationrods 25 follow the contours of the bone surface. Accordingly, theosteointegration rods 25 can be made of malleable materials. In anotherembodiment, the osteointegration rods 25 can be configures to penetratethe bone surface as shown in FIGS. 3-4. The osteointegration rods 25have a sufficient surface area to allow for the transfer of the forcesof the implanted system onto the bone. According to one embodiment, allof the surfaces of the osteointegration rods 25 include materials or istreated to promote bone growth.

As shown in FIGS. 3-4, the base component 10 includes a plurality ofopenings 11, 19, 22, 24. Opening 11 has a diameter sized to receivestandard K-wires that are used to temporarily locate the base component10 on the bone. Openings 19, 22, 24 are sized to receive fasteningmembers used to permanently secure the base component to the bone.Openings 19 define through holes for compression screws and opening 22,24 are configured to receive locking screws. In one embodiment, thelocking screw openings 22, 24 are threaded. As shown in FIGS. 3-4, theopenings 22, 24 are located near the mounting end 15 of the basecomponent in order to receive fasteners which securely fix the basecomponent to the bone and maximize pull-out forces. The openings 22, 24may also have divergent bores trajectories to further maximize the pullforces required to remove the base component from the bone. The numberand trajectories of the openings may be varied in alternate embodiments.A post access port 13 is provided near the mounting end 15 of the basecomponent 10 (see for example FIG. 5). The post access port 13 is sizedto receive a tool that allows for disassembly of a mount member (notshown) from the base component 10 by pushing the post 23 of the mountmember out of the base component. Openings 26 additionally alter thestress distribution on cortical bone surface that can stimulate boneyremodelling. Bone can grow up into these holes further adding shearstrength to the bone implant interface.

Turning now to FIG. 6, a presently preferred embodiment of a basecomponent 10 that is mountable to a femur is shown. The base component10 includes a body having an elongated portion 12 and a curved portion14. The body is generally narrow having a rounded first end 16 and asquared-off second end 18. In various embodiments, the second end 18 isconfigured to attach to mounts and/or devices for absorbing energy at ajoint. As shown in FIG. 6, the upper surface of the body is a generallycurved such that a center of the body is thicker than the edges of thebody. The base component 10 also includes rounded edges in order tominimize sharp edges that may otherwise cause damage to surroundingtissues when the component is coupled to body anatomy such as the femur.

As shown in FIG. 7, the body also includes a plurality of openings 20and 21 configured to receive fastening members. The openings 20 and 21are generally aligned along the center of the elongate portion of thebody. The openings 20 and 21 on the elongated portion of the body 12 arepositioned such that the fastening members contact the osteointegrationarea of the femur. According to one embodiment, the openings 20 and 21are configured to accept compression screws that compress the basecomponent 10 onto the bone surface. The compression screws may becancellous screws of either uni-cortical or bicortical design. Theopenings 20 are sized to accommodate a particular screw size.

Additionally, two openings 22, 24 are provided on the curved portion 14of the body. The openings 22, 24 are positioned such that fasteningmembers inserted there through (as shown in FIGS. 11-12) will beconfigured closer to the center of rotation of the femur. In oneembodiment, the fastening members 22, 24 are locking screws and theopenings 22, 24 include threads for engaging like structure of thelocking screws. It is to be recognized that locking screws securelyanchor the base to the bone such that the relative motion between thebase component 10 and the mating bone is less than 150 microns. Thelocking screws function to stabilize the base component as micro-motionsof the base component prevent osteointegration of the base component.

Additionally, the openings 20, 21, 22, 24 can be oriented to providefastening member trajectories that maximize pull out forces therebyminimizing the possibility that the base component is separated from thebone. According to one embodiment, the trajectories of the openings areoriented such that the opening trajectories are normal or approximatelynormal to the shear loading forces on the base component 10. Forexample, the two openings 22, 24 on the curved portion 14 of the bodyhave differing fastening member trajectories as the posterior opening 22orients a fastening member at a downward trajectory (See FIG. 18), andthe anterior opening 24 orients a fastening member at an upwardtrajectory (See FIG. 19).

The openings 20, 21, 22, 24 can be countersunk to allow the fasteningmembers to sit below the surface of the base body as shown in FIG. 10.In one specific approach, the openings 20 are sized to accommodate 4.0mm screws. In other approaches, the openings 20 may be sized toaccommodate 3.5 mm, 4.5 mm, 5.0 mm, or 6.5 screws.

In a preferred embodiment, two openings 20 on the elongated portion ofthe base component 10 are sized and threaded to accommodate 3.5 mmbicortical compression screws. The most inferior opening 21 on theelongated portion of the base component is sized to accommodate a 6.5 mmunicortical compression screw. The openings 22, 24 on the curved portion14 of the body are sized and threaded to accommodate 4.5 mm lockingscrews.

While screws are used to fix the base component 10 to the bone, thoseskilled in the art will appreciate that any fastening members known orpreviously developed may be used to secure a base component to a bone.For example, in other embodiments, a fastening device similar to a molybolt or a toggle bolt is used to secure the base component to a bone.Additionally, FIGS. 1-11 illustrate a base component 10 having fivefastener openings 20, 21, 22, 24; however, it is contemplated that otherembodiments of the base component may be have any number of openingshaving various screw trajectories.

Referring back to FIG. 6, the base component 10 also includes aplurality of holes 26 that may be used for aligning the base componenton the bone. Optionally, the base component 10 may include a pluralityof holes (not shown) to promote bone in-growth thereby improving basecomponent stability. In this regard, K-wires can be configured throughthe holes 26 to maintain alignment of a base to bone during itsaffixation thereto by fastening members.

FIG. 7 illustrates a view of the inner surface 28 of the base component10. As shown, the inner surface 28 is a roughened or etched surface toimprove osteointegration. Alternatively, the inner surface 28 ismodified to induce bone growth. Thus, osteointegration can be obtainedthrough mechanical interlocking or as a result of chemical loading. Forexample, the inner surface 28 may be coated with bone morphogenicprotein 2 (BMP-2), hydroxyapatite (HA), titanium, cobalt chrome beads,or any other osteo-generating substance. According to one embodiment, atitanium plasma spray having a thickness of approximately 0.033in.±0.005 in. is applied to the inner surface 28. In another embodiment,a HA plasma spray having a thickness of approximately 35 μm±10 μm isapplied to facilitate osteointegration.

As shown in FIG. 7, the inner surface 28 has a first radius of curvatureat the proximal end 30 of the base component 10 and a second radius ofcurvature at the distal end 32 of the inner surface where the firstradius of curvature is greater than the second radius of curvature.Alternatively, the first radius of curvature is less than the secondradius of curvature. In another embodiment, the first and second radiiof curvature are approximately equal.

Additionally, as best seen in FIG. 8, the inner surface 28 is generallyhelical in shape when moving from the proximal end 30 of the basecomponent 10 to the distal end 32 of the base component. That is, theinner surface 28 twists when moving from the top of the inner surface tothe bottom of the inner surface. The helical nature of the inner surface28 generally follows contours of the femur when moving distally (downthe femur) and posteriorly (front to back). Accordingly, the contouringof the inner surface 28 helps to reduce the overall profile of the basecomponent 10 when affixed to the medial surface of the femur.Additionally, the contouring of the inner surface 28 increases thesurface area in which the base component contacts the femur therebyimproving load distribution.

Additionally, as shown in FIG. 8, the end 18 of the base component 10includes a bore 40. The bore 40 is sized to receive a post (See FIG. 9B)of a mounting member 15. According to one embodiment, the bore 40 has auniform inner diameter. Alternatively, the bore 40 is tapered (e.g.,inner diameter decreases when moving away from the opening of the bore).In yet another embodiment, a funneling feature 46 is provided around theopening of the bore 40 as shown in FIG. 9A. The funneling feature 46acts as a guide to facilitate the insertion of the mounting member intothe bore. The end 18 of the base component 10 also includes alignmentmembers 42 for properly orienting the mounting member (not shown) on thebase component.

FIGS. 9B-C illustrate a cross-section view of one embodiment of the bore40 of the base component 10 including a sleeve 44. The sleeve 44 acts asa sacrificial piece of material that prevents damage to the bore 40while providing a good secure fit between the mounting member and thebase component. In one embodiment, the sleeve 44 is press fit into thebore 40. The inner diameter of the sleeve 44 can be uniform oralternatively, the outer diameter is variable. Additionally, one or morerings can be provided on the outer diameter of the bore 40. As thesleeve 44 is inserted into the bore 40, the rings 48 on the outerdiameter deform thereby providing a secure connection between the basecomponent 10 and the mounting member 15. Additionally, the sleeve 44facilitates the removal of the mounting member 15 from the basecomponent 10. Additionally, interpositional segments can be placed atthe end 18 of the bone component 10 to change the length of the basecomponent. The two part base/mounting member system provides a methodfor good attachment of the base to the bone and a more simple surgicaltechnique for installing the link assembly. It also allows a sheath (notshown) and/or wear components of the link/mounting member assembly to beremoveable and/or replaceable without removing or replacing the basecomponents. It further allows the wear components of the link/mountingmember assembly and the base components to be different materials. Forexample, the base components can be titanium or titanium alloy whichpromote osteo-integration and the wear components can be much hardermaterials such as cobalt chrome (e.g., Biodur CCM Plus), ceramic, orother durable materials that produce a minimal amount of particulatematerial or, if particulate material is generated, the smallest size ofparticulate material.

With reference to FIG. 10A, another embodiment of the inner surface 28of a base component is shown having a plurality of spikes 34 projectingout of the inner surface. While the spikes 34 shown in FIG. 10A aresolid, it is contemplated that the spikes (not shown) may also includean inner bore (similar to a needle) that promotes for bone in-growth.According to one embodiment, the spikes 34 may be positioned anywhere onthe inner surface 28 (e.g., randomly dispersed or concentrated in one ormore areas) in order to preserve critical anatomy (e.g., periostealvessels), improve pull out forces (i.e., more force required to pullcomponent away from bone), and/or stimulate osteointegration. The spikes34 may extend approximately 2 mm from the inner surface 28 of the basecomponent 10. As those skilled in the art will appreciate, any usefulspike length is contemplated. In yet another embodiment, one or morehollow tabs 36 are provided on the inner surface 28 as shown in FIG.10B. The tabs 36 may be any shape (e.g., rectangular, triangular, or anypolygonal shape) having a hollow opening (i.e., the walls of the tabform the perimeter of the shape) thereby promoting osteointegration andstability to the base component 10.

FIGS. 11-12 illustrate the base component 10 affixed to the medialsurface of the femur. As best seen in FIG. 12, the base component 10 hasa generally low-profile when mounted to the bone. The base component 10is affixed to the medial surface of the femur in order to preservecritical anatomy such as, but not limited to, medial collateralligaments while positioning the second end 18 of the base component asclose to the center of rotation of the femur. Moreover, the curvedportion 14 of the base component 10 is offset from the surface of thebone to avoid critical structure while maintaining a low profile of thedevice.

The base component 10 shown in FIGS. 1-12 is configured to be fixed tothe medial surface of the left femur. It is to be appreciated that amirror image of the base component 10 shown in FIGS. 1-12 would befixable to the medial surface of the right femur. In an alternateembodiment, the base component may be configured to be fixed to thelateral surface of the left or right femur. In yet another approach,base components may be fixed to both the lateral and medial surfaces ofthe left or right femur.

A presently preferred embodiment of base component 60 that is mountableto the medial surface of the tibia is depicted in FIG. 13. As shown, thetibial base component 60 has an overall curved shape. The base component60 includes a main body portion 62 and an arm portion 64. The armportion 64 of the base component 60 is shaped to position a link orabsorber assembly approximately perpendicular to the tibial plateau toprovide desired alignment across the joint. Alternatively, the armportion 64 may be angled relative to the tibial plateau in order toprovide some torque across the joint. The upper surface of the body is acurved convexly where the center of the body is thicker than the edgesof the body. The base component 60 also includes rounded edges in orderto minimize sharp edges that may otherwise cause damage to surroundingtissues when the component is coupled to the tibia. The main bodyportion 62 is generally narrow and includes a rounded first end 66 and asquared-off second end 68. In various embodiments, the second end 68 isconfigured to attach to mounts and devices for absorbing energy at ajoint. The main body portion 62 is the portion of the base component 60that contacts the tibia. The arm portion 64 is offset laterally from thebone (i.e., the arm portion does not contact the tibia). While the armportion 64 of the base component 60 is offset from the bone, the basecomponent defines a low-profile when mounted to the bone.

As shown in FIGS. 13-17, the base component 60 also includes a pluralityof openings 70. The openings 70 are aligned along the center portion ofthe base component 60. The openings 70 are positioned such that thescrews contact the osteointegration area of the tibia. Additionally, twoopenings 72, 74 are provided on the arm portion 64 of the base component60. The two openings 72, 74 are positioned such that the screws (asshown in FIGS. 18-19) will be mounted closer to the mounting location ofthe mounting member (not shown) at the end of the base component.

Additionally, the openings 70, 72, 74 are oriented to provide differingtrajectories for fastening members that maximize pull forces therebyminimizing the possibility that the base component 60 is separated fromthe bone. According to one embodiment, the opening trajectories areoriented such that the hole trajectories are normal or approximatelynormal to the shear loading forces on the base component 10. Forexample, as shown in FIG. 19, the two openings 72, 74 on the arm portion64 of the base component have differing trajectories, the posterioropening 72 orienting a fastening member at an upward trajectory, and theanterior opening 74 orienting a fastening member at a slightly upwardtrajectory.

The openings 70, 72, 74 can be countersunk to allow the heads offastening members to sit below the surface of the body as shown in FIGS.16-17. According to one embodiment, the openings 70, 72, 74 are sized toaccommodate 4.0 mm diameter fastening members. In other embodiments, theopenings 72, 74 may be sized to accommodate 3.5 mm, 4.5 mm, or 5.0 mmdiameter fastening members. Additionally, the inner bores of theopenings 70, 72, 74 may be threaded for use with locking screws (i.e.,head of the screw also includes threads that engage threads in the boreof the screw hole). In preferred approaches, a combination ofcompression screws and locking screws are used to secure the basecomponent 60 to a bone.

While screws are used to fix the femoral and tibial base components 10,60 to the bone, those skilled in the art will appreciate that anyfastening members known or developed in the art may be used toaccomplish desired affixation. Although the base components 10, 60depicted in FIGS. 6-7 and 13-14 illustrate structure having fiveopenings, it is contemplated that other embodiments of the basecomponent may be have any number of openings. Additionally, the openingsmay be oriented such that fastening members will have differenttrajectories.

As shown in FIG. 13-17, the tibial base component 60 also includes aplurality of holes 76 that may be used during alignment of the basecomponent 60 on the tibia and sized to receive structure such as aK-wire. Optionally, the base component 60 may include a plurality ofholes (not shown) to promote bone in-growth thereby improving basecomponent stability.

FIG. 14 illustrates a perspective view of the inner surface 78 of thetibial base component 60. The inner surface 78 represents the base tobone surface arch required to support expected shear forces resultingfrom 60 lbs. of load carrying. As shown in FIG. 14, the inner surface 78is a roughened surface for improving osteointegration. Alternatively oradditionally, the inner surface 78 is coated to induce bone growth. Forexample, the inner surface 78 may be coated with bone morphogenicprotein 2 (BMP-2) or hydroxyapatite, titanium, cobalt chrome beads. Asshown in FIGS. 15A-15B, the inner surface 78 is a contoured surface thatpromotes good contact between the base component 60 and the tibia.Accordingly, the inner surface facilitates the base component 60absorbing and transferring load forces from the base component to thetibia. Similar to the embodiments disclosed in FIGS. 10A-10B, the innersurface 78 of the base component 60 may include one or more spikes ortabs.

FIGS. 15A-B are cross-sectional views of the inner surface 78 of thetibial base component 60. As shown in FIG. 15A, the inner surface 78 hasan osteointegration coating applied to the top surface 80 and the edges82 of the inner surface 78. In another approach, the osteointegrationcoating (not shown) is only applied to the inner surface. FIG. 15Billustrates a another embodiment where a portion of the osteointegrationcoating 84 on the inner surface 78 is over-contoured (i.e., extendsabove the plane of the inner surface 78). The over-contoured coating 84surface is compressed when the tibial base component 60 is affixed tothe bone, thereby preventing micro-motion of the base component. Theover-contoured coating 84 also concentrates the compressive forces onthe middle of the inner surface 78.

With reference to FIGS. 16-17, the tibial base component 60 has agenerally low-profile when mounted to the bone. The base component 60 ismounted to the medial surface of the tibia in order to preserve criticalanatomy such as, but not limited to, medial collateral ligaments whilepositioning the second end 68 of the base component as close to thepivot point of the tibia. As best seen in FIG. 16, the arm portion 64 ofthe base component 60 is also offset from the surface of the tibia toavoid critical structure while maintaining a low profile of the basecomponent.

The tibial base component 60 shown in FIGS. 13-17 is configured to befixed to the medial surface of the left tibia. As those skilled in theart will appreciate, a mirror image of the base component 60 shown inFIGS. 13-17 would be fixable to the medial surface of the right tibia.Additionally, the base component may be configured to be fixed to thelateral surface of the left or right tibia. In another approach, thebase component may be configured to be coupled to lateral surfaces ofboth the tibia and fibula. In yet another embodiment, base componentsmay be fixed to both the lateral and medial surfaces of the left orright tibia.

FIGS. 18-19 illustrate one embodiment of an extra-articular implantablemechanical energy absorbing system 100 that is coupled to the secondends 18, 68 of the femoral and tibial base components 10, 60,respectively. Through the connections provided by the base components10, 60, the mechanical energy absorbing system 100 can function toreduce desired forces from a knee joint. It is also to be recognizedthat the placement of the bases on the bones is made such that furtherprocedures, such as a TKA, can be conducted at the joint while leavingthe bases in place but after removing the absorbing system.Additionally, the absorbing system can be replaced without having toreplace the base components resulting in removal of all of the wearcomponents.

The various embodiments of the base component may be made from a widerange of materials. According to one embodiment, the base components aremade from metals and alloys such as, but not limited to, Titanium,stainless steel, Cobalt Chrome. Alternatively, the base components aremade from thermoplastic materials such as, but not limited to,polyetheretherketones (PEEK). Various embodiments of the base componentsare rigid structures.

FIGS. 20A-B illustrate a tibial base component 110 and a femoral basecomponent 120 having partially flexible regions 112, 122 for flexingand/or twisting. As shown, each base component 110, 120 includes a rigidsection 114, 124 and the flexible region 112, 122. The rigid section114, 124 of the base components 110, 120 are mountable to the bone andcan include an osteointegration surface. The flexible region 112, 122 ofthe base components 110, 120 extends from the base and providesadditional load bypass capabilities. The flexible regions 112, 114 ofthe base components 110, 120 apply a linear or nonlinear spring forcewhen the flexible region is deflected. Additionally, the flexibleregions 112, 122 provide adjustability in positioning of the basecomponent on the bone by minimizing some degree of precision required tofind the proper mounting location on the bone. It is also contemplatedthat the flexible regions 112, 122 can also be used to absorb additionalforces in an overload situation to protect the base component 110, 120stability.

Various other embodiments of bases are contemplated. Such bases canincorporate one or more of the previously described features or canembody structure separate to itself.

In particular, as shown in FIGS. 21A and B, one or more of the bases caninclude adjustment structures. Here, a base 130 can include two pieces132, 134 which are slideable with respect to each other. A top piece 132can be formed of a material through which fastening members can beforceably inserted without originally including one or more throughholes, whereas the bottom piece 134 can include previously machinedthrough holes. Thus, the top piece 132 can be adjusted with respect tothe bottom piece and the adjusted juxtapositional relationship can beset with the fasteners employed to attach the assembly to body anatomy.Accordingly, such alterations can translate into adjusting as desiredthe action of absorber components of an energy absorbing assembly. It isalso contemplated that the materials be selected for the bases so thatthey define flexible structure intended to absorb forces. Such anapproach is useful where the sub-structure of an energy absorbing deviceincludes a defined fully loaded position so that further loads aretransferred to the flexible bases.

Moreover, a base 136 can be configured to attach to cortical bone asshown in FIGS. 22-25. In these approaches, the base 136 can have anextension 138 (See FIG. 22) including mounting holes so that attachmentto cortical bone is possible. Additionally, the base 136 can include aportion 140 extending about lateral surfaces of a bone to thereby beconnectible to cortical bone (See FIGS. 23-25). As depicted in FIGS.22-24, certain of these approaches can also include detachable link pinsubstructures 142 for releasably attaching to an energy absorbing deviceor other structures. Moreover, as with all disclosed approaches, theseembodiments can include surfaces 146 promoting boney in-growth, such asindicated in FIGS. 23 and 24. Additionally, as specifically shown inFIG. 25, the removable pin substructure 142 can be formed in anextension 150 that is itself removable from the base 136.

In yet other approaches, the base component can include structure whichrelies on surrounding anatomy for additional support. For example, asshown in FIG. 26, a base 160 can include structure extending to andoverlaying a fibula 162. Further, as shown in FIG. 27, a base assembly170 can include multiple pieces attached to opposite sides of a bone andcan further include a restraining cross-bar 172 extending from one ofthe multiple pieces to another.

Similarly, as depicted in FIG. 29, support for an energy absorbing orother device 180 can be obtained from opposite sides of a joint. Forinstance, one end of the device can be supported by a laterally placedbase 182 and another supported by a medially placed base 184. To do so,a rod 186 can be positioned across an interior of a bone from alaterally configured implanted device to a medial side base 184. In thisway, where necessary, diseased or complex anatomy can be avoided so thata good fit to bone can be achieved.

Turning now to FIGS. 29-32, yet further contemplated embodiments ofbases 190 are illustrated. Such bases can have simple through holes 192(FIGS. 29 and 32) for fastening members or such holes can includecountersinks 194 (FIG. 31). Additionally, the fastening holes can definescrew head sockets 196 as shown in FIG. 30. Moreover, the contemplatedbases can embody various approaches for accomplishing connection to thebone such as by including spikes 198 (FIGS. 29 and 32) or rotatablespurs 200 (FIG. 30). Furthermore, the bases 190 can include small holes202 such as those having a diameter of less than 1 mm for boney,interlocking in-growth (FIG. 29).

Finally, as shown in FIG. 33, the base 210 can include a slotted region212 for receiving corresponding structures. Also, the holes 214 formedon a base 216 can be numbered or otherwise identified to assist aphysician in selecting proper fastening members.

The various embodiments described above are provided by way ofillustration only and should not be construed to limit the claimedinvention. Those skilled in the art will readily recognize variousmodifications and changes that may be made to the claimed inventionwithout following the example embodiments and applications illustratedand described herein, and without departing from the true spirit andscope of the claimed invention, which is set forth in the followingclaims. In that regard, various features from certain of the disclosedembodiments can be incorporated into other of the disclosed embodimentsto provide desired structure.

What is claimed:
 1. A base component mountable to a bone, the componentcomprising: a body having a first end, a second end, an outer surfaceconfigured to face away from the bone surface when the base is mountedon the bone, and an inner surface configured to face the bone surfacewhen the base is mounted on the bone, wherein the body is a non-planarbody such that the second end of the body is elevated relative to thefirst end such that the inner surface of the entire second end does notcontact bone when the inner surface of the first end is mounted on thebone, the second end including at least one tab extending away from thesecond end; a plurality of openings provided on the body, wherein theopenings include a first set of one or more openings configured toreceive a compression fastener, a second set of one or more openingsconfigured to receive a locking fastener, and a third set of one or moreopenings configured to receive an alignment wire; and a removablemounting member removably attached to the elevated second end of thebody, the removable mounting member including at least one recessremovably receiving said at least one tab therein, and wherein the bodyis configured to locate the mounting member in order to position akinematic load absorber for reduction of forces on a joint.
 2. A basecomponent according to claim 1, wherein: the inner surface includes abone-contacting portion and an offset non-bone-contacting portion; thebody includes first and second portions; the first end and thebone-contacting portion are located in the body first portion; thesecond end and the non-bone-contacting portion are located in the bodysecond portion; and the first and second body portions are angledrelative to each other.
 3. A base component according to claim 2,wherein: the body first portion includes two ends which define a firstdirection; the body second portion includes two ends which define asecond direction; one of the first portion ends and one of the secondportion ends are joined; and the at least one tab extends along saidsecond direction.